JP6523610B2 - Syringe - Google Patents

Description

  The present invention relates to a syringe, and more particularly to a measure to reduce the sliding resistance of a gasket inserted into the outer cylinder of the syringe.

  Conventionally, a syringe provided with an outer cylinder portion, a gasket and a plunger is known (see, for example, Patent Document 1). In this syringe, an end wall is provided at one end of the outer cylindrical portion, a nozzle is provided through the end wall, and a gasket connected to the tip of the plunger is inserted through the opening at the other end of the outer cylindrical portion Is inserted in the

  In this conventional syringe, a storage chamber is formed between the end wall of the barrel and the gasket. When pushed by the plunger and the gasket moves forward, the above-mentioned storage chamber contracts and the fluid in the storage chamber flows out of the syringe through the nozzle. On the other hand, when the plunger is pulled forward and the gasket moves backward, the above-mentioned storage chamber is expanded and fluid outside the syringe flows into the storage chamber through the nozzle.

JP, 2009-165524, A

  However, in the case of the conventional syringe, the outer cylinder and the gasket are in sliding contact with each other so that the liquid in the storage chamber does not leak from the radial gap between the outer cylinder and the gasket. The sliding resistance between them makes it difficult to move the plunger.

  In particular, when pulling the plunger, unlike when pushing the plunger, it is necessary to adjust the force so that the gasket does not come off the outer cylinder. From this, when pulling a plunger, there existed a problem that operation of a plunger was difficult to operate compared with the case where a plunger is pushed.

  The present invention has been made in view of such a point, and an object thereof is to make it easier for a syringe to pull a plunger toward the front than when the plunger is pushed.

  The present invention comprises an end wall through which a nozzle passes, an outer cylindrical portion having the end wall connected to one end, and a gasket sliding in the outer cylindrical portion back and forth, wherein the outer cylindrical portion is It has a liquid reservoir adjacent to the rear side of the sliding portion, and the liquid of the liquid reservoir enters the sliding portion of the gasket along with the rearward sliding of the gasket to lubricate the sliding portion Syringe.

  Further, the outer cylindrical portion of the syringe of the present invention is adjacent to the front side of the gasket and communicates with the nozzle, and communicates with the liquid storage portion adjacent to the side of the gasket. A liquid passage may be formed, and the liquid in the storage chamber may be sent to the liquid reservoir through the liquid passage in accordance with the contraction of the storage chamber due to the forward sliding of the gasket.

  Further, the outer cylinder portion of the syringe of the present invention includes a rib protruding radially inward from the inner peripheral wall, and the portion of the gasket which rides on the rib when sliding in the front and rear direction is deformed to a recessed portion The liquid passage may be formed in a recess of the gasket.

  In addition, the syringe of the present invention includes a plunger connected to the gasket, and the gasket is pushed forward by the plunger to squeeze the rib and closes the nozzle, and then the plunger is further forwardly moved by the plunger The storage chamber may be contracted by being pressed to the end wall and elastically deformed.

  Further, the rib of the outer cylinder portion of the syringe of the present invention may be formed such that the axial length is longer than the axial length of the sliding portion of the gasket.

  Moreover, the rib of the outer cylinder part of the syringe of this invention may be made to space apart in the circumferential direction of one or the said outer cylinder part, and may be formed in multiple numbers.

  Further, the gasket of the syringe of the present invention has at least one of a small diameter portion separated from the outer cylinder portion and a large diameter portion continuously formed on the front side of the small diameter portion, and the outer cylinder portion and the above The sliding portion may be formed between the large diameter portion, and the liquid reservoir may be formed in a radial gap between the outer cylindrical portion and the small diameter portion.

  Further, the rib of the outer cylinder portion of the syringe of the present invention may be formed such that the axial length is longer than the axial length of the large diameter portion of the gasket.

  Further, in the outer cylindrical portion of the syringe of the present invention, a groove extending in the axial direction may be formed in the inner peripheral wall, and the liquid passage may be formed inside the groove.

  According to the present invention, the liquid accumulated in the liquid reservoir of the syringe is supplied to the sliding portion of the gasket as the gasket slides rearward, and the liquid in the liquid reservoir is lubricated in the sliding portion of the gasket. By using it as an agent, the sliding resistance between the outer cylinder and the gasket can be reduced. This reduction in sliding resistance makes it easier to pull the plunger forward.

FIG. 1 is a longitudinal sectional view of a syringe according to an embodiment of the present invention. FIG. 2 is a longitudinal cross-sectional view of the vicinity of a nozzle of a syringe according to an embodiment of the present invention. FIG. 3 is a longitudinal cross-sectional view of the vicinity of the nozzle of the syringe when the gasket rides on the rib. FIG. 4 is a cross-sectional view taken along line A-A of FIG. FIG. 5 is a vertical cross-sectional view of the vicinity of the nozzle of the syringe immediately after the tip of the gasket closes the through hole in the end wall. FIG. 6 is a graph showing the results of a sliding performance test on syringes of the present invention and a conventional product.

  Hereinafter, the syringe concerning one embodiment of the present invention is explained in detail based on a drawing. In addition, one embodiment described below is an illustration, and the present invention is not limited to one embodiment.

(Whole configuration of the syringe)
First, the entire configuration of the syringe (10) will be described. As shown in FIG. 1, the syringe (10) comprises a nozzle (21), an end wall (24), an outer cylinder (20), a gasket (30) and a plunger (40).

  The nozzle (21) is formed in an elongated shape. The nozzle (21) is provided through the center of the end wall (24). The end wall (24) is attached to one end of the outer cylinder (20). The axial center of the nozzle (21) and the axial center of the outer cylinder portion (20) substantially coincide with each other. The other end of the outer cylindrical portion (20) is open. The gasket (30) is inserted into the inside of the outer cylinder (20) through the opening. A storage chamber (4) is formed between the end wall (24) of the outer cylindrical portion (20) and the gasket (30). The internal passage of the nozzle (21) and the storage chamber (4) communicate with each other.

  A gasket (30) is connected to the end of the plunger (40). When the gasket (30) is moved forward by being pushed by the plunger (40), the above-mentioned storage chamber (4) contracts and the liquid (5) in the storage chamber (4) is discharged through the nozzle (21) of the syringe (10). Flow out to the outside. On the other hand, when the plunger is pulled forward and the gasket moves backward, the above-mentioned storage chamber (4) expands and the liquid (5) outside the syringe (10) passes through the nozzle (21) to the storage chamber (4). To flow.

(The lubrication structure of the sliding part of the syringe)
Next, the lubricating structure of the sliding portion in the syringe (10) will be described.

-Reservoir chamber-
The syringe (10) is provided with a fluid reservoir (3) as a fluid reservoir for storing the liquid (5) supplied to the sliding portion of the syringe (10).

  As shown in FIG. 2, the gasket (30) is continuously formed on the front side of the small diameter portion (31) and the small diameter portion (31) radially spaced from the inner peripheral wall (22) of the outer cylinder portion (20). One front large diameter portion (32) as a large diameter portion is provided. Further, a rear large diameter portion (33) is formed continuously to the rear side of the small diameter portion (31). The outer peripheral wall (35, 36) of these large diameter portions (32, 33) is in sliding contact with the inner peripheral wall (22) of the outer cylinder portion (20). The outer peripheral wall (35, 36) of the large diameter portion (32, 33) and the inner peripheral wall (22) of the outer cylinder portion (20) are sliding portions (11) of the syringe (10).

  In addition, although the gasket (30) of this one embodiment has one front large diameter part (32) and one small diameter part (31) respectively, it is not limited to this, and the front large diameter part (32) A plurality of sets may be formed continuously in the longitudinal direction of the gasket (30) as one set of the small diameter portion (31) and the small diameter portion (31). Alternatively, the rear large diameter portion (33) may be formed continuously on the rear side of the rearmost small diameter portion (31) of the gasket.

  The sliding part (1) between the inner peripheral wall (22) of the outer cylinder part (20) and the outer peripheral wall (35) of the front large diameter part (32) is a gasket when pulling the plunger (40) to the front The liquid (5) in the liquid storage chamber (3) of the gasket (30) is configured to enter along with the sliding of (30). By this, this liquid (5) acts as a lubricant and the gasket (30) moves smoothly.

  Further, in the gasket (30), the intersection of the outer peripheral wall (35) of the front large diameter portion (32) and the end face (37) on the back side is rounded (see 50 in FIG. 2). This makes it easier for the liquid (5) in the liquid storage chamber (3) to enter the sliding portion (1) of the front large diameter portion (32) as compared to the case where the above-mentioned intersecting portion is formed by the corner portion. There is. This allows the gasket (30) to move more smoothly.

  Here, although the sliding area of the front large diameter part (32) and the sliding area of the rear large diameter part (33) in this gasket (30) are substantially the same, for example, the sliding of the entire gasket (30) The ratio of the sliding area of the front large diameter portion (32) to the dynamic area may be larger than the ratio of the sliding area of the rear large diameter portion (33). Since the liquid (5) of the liquid storage chamber (3) is supplied to the front large diameter part (32) side, the sliding area of the front large diameter part (32) is the sliding area of the rear large diameter part (33) By making them larger, the gasket (30) will move more smoothly.

  In addition, it prevents that the ratio of the sliding area of the rear large diameter part (33) to the sliding area of the entire gasket (30) becomes larger than the ratio of the sliding area of the front large diameter part (32) Absent. In one embodiment, the gasket (30) of the syringe (10) is configured such that the liquid (5) in the liquid reservoir (3) does not enter the sliding portion of the rear large diameter portion (33). The liquid (5) in the liquid storage chamber (3) is not leaked to the rear than the rear large diameter portion (33), but the invention is not limited thereto. The gasket (30) may move more smoothly as 5) enters the sliding portion of the rear large diameter portion (33).

-Fluid passage-
Further, as shown in FIGS. 3 and 4, the syringe (10) is provided with a fluid passage (4) communicating the storage chamber (4) of the outer cylinder portion (20) with the fluid reservoir chamber (3) of the gasket (30). 2) is provided.

  The outer cylindrical portion (20) includes a plurality of ribs (23) projecting radially inward from the inner peripheral wall (22). These ribs (23) are located closer to the end wall (24) of the outer cylindrical portion (20). When the plunger (40) is pushed, the gasket (30) slides forward. The gasket (30) is made of an elastic body, and along with the forward sliding of the gasket (30), the outer peripheral wall (35) of the front large diameter portion (32) of the gasket (30) is the rib (23) described above Ride on (see Figure 3). Then, the portion on which the vehicle rides up is elastically deformed, and as shown in FIG. 4, a depressed portion (34) is formed in the front large diameter portion (32). The above-mentioned liquid passage (2) is formed in the inside of this recess (34).

  The rib (23) has an axial length (L1 in FIG. 3) longer than an axial length (L2 in FIG. 3) of the sliding contact portion of the outer peripheral wall (35) of the front large diameter portion (32) And the axial length of the sliding portion of the outer peripheral wall (35) of the front large diameter portion (32) of the gasket (30) and the axial length of the small diameter portion (31) of the gasket (30) It is formed shorter than (L3 in FIG. 3). By making the axial length of the rib (23) longer than L2, the storage chamber (4) of the outer cylinder portion (20) and the liquid storage chamber (3) of the gasket (30) can be reliably communicated. By making the axial length of the rib (23) shorter than L3, communication between the storage chamber (4) of the outer cylindrical portion (20) and the sliding portion of the rear large diameter portion (33) is prevented. ing.

  When the entire front large diameter portion (32) rides on the rib (23), the storage chamber (4) of the outer cylindrical portion (20) and the gasket (30) in the liquid passage (2) of the recessed portion (34) It communicates with the liquid storage chamber (3). By this communication, a part of the liquid (5) in the storage chamber (4) flows into the liquid storage chamber (3). The liquid in the storage chamber (4) is supplied to the sliding portion (1) through the liquid storage chamber (3). Since both sides of the liquid passage (2) are sliding parts (1), the liquid (5) in the storage chamber (4) is supplied to the sliding parts (1) on both sides while flowing through the liquid passage (2) Be done.

  The rib (23) is formed in a linear shape along the axial direction of the outer cylindrical portion (20). The ribs (23) are not limited to linear ones, but may be helical ones, diagonal ones, etc., but the axial length is the outer peripheral wall (35) of the front large diameter part (32) It needs to be longer than the axial length of the sliding contact portion. Otherwise, the length of the recessed portion (34) is insufficient, and the liquid passage (2) of the recessed portion (34) allows the storage chamber (4) of the outer cylindrical portion (20) and the liquid storage chamber (30) of the gasket (30). It is because it can not communicate with 3).

  Further, four ribs (23) are arranged at intervals of 90 ° in the circumferential direction around the axial center of the outer cylinder portion (20). The number of ribs (23) and the distance between the ribs (23) are merely examples, and the number and distance between them are not limited to one embodiment, and the number of ribs (23) may be other than four. The circumferential intervals between the ribs (23) and the ribs (23) may be unequal pitches.

  In addition, the end face of the rib (23) is formed flat. In one embodiment, the length of the rib (23) is 5 mm, and the width of the rib (23) is 0.3 mm. The height of the rib (23) is set to 0.1 mm. By flattening the tip end face of the rib (23), the rib (23) is a gasket when the gasket (30) rides on the rib (23), as compared to the case where the tip of the rib (23) has an acute angle. (30) can be made difficult to damage. Further, in the rib (23), the gasket (30) is less likely to be damaged by providing a roundness at the intersection of the both side surfaces and the flat tip surface.

  In addition, at the end of the opening side of the outer cylindrical portion (20) in the axial direction, the height of the rib (23) gradually increases from the opening side of the outer cylindrical portion (20) toward the end wall (24) It may be configured to be high. Thus, by inclining the end of the rib (23), when the plunger (40) is pushed, the gasket (30) can easily get on the rib (23).

-Containment room-
Moreover, even if this syringe (10) is advanced until the gasket (30) pushed by the plunger (40) closes the through hole (25) of the nozzle (21) of the end wall (24), as shown in FIG. As shown, a gap (S) as a storage chamber (4) is formed between the portion (26) outside the outer peripheral edge of the through hole (25) in the end wall (24) and the gasket (30) . That is, when the gasket (30) closes the through hole (25) of the end wall (24), the gasket (30) does not contact the end wall (24) without any gap.

  The front large diameter portion (32) of the gasket (30) has a conical tip (38). On the other hand, the end wall (24) of the outer cylindrical portion (20) is formed in a tapered shape expanding in diameter from the outer peripheral edge of the through hole (32) toward the outer peripheral edge of the end wall (24). The conical tip (38) described above and the through-hole (32) of the end wall (24) described above both have the same axial center, and the apex angle of the conical tip (38) has the end wall ( Even if the top of the conical tip (38) blocks the through hole (32) of the end wall (24) because it is smaller than the taper angle of 24), the front large diameter portion (32) and the end wall (24) A gap (S) constituting the storage chamber (4) is formed between them.

  The rib (23) of the outer tubular portion (20) is formed such that the end on the axial forward side is in contact with the outer peripheral edge on the axial forward side of the outer tubular portion (20). The liquid passage (2) of the recess (34) of the gasket (30) generated by the opening (30) opens in the gap constituting the above-mentioned storage chamber (4).

  From this state, when the plunger (40) is further pushed, the conical tip (38) elastically deforms and the above-mentioned storage chamber (4) contracts and the liquid (5) becomes a gasket through the liquid passage (2) It is supplied to the liquid storage chamber (3) of (30). Since the nozzle (21) is closed by the conical tip (38), the liquid (5) in the storage chamber (4) can easily move toward the liquid storage chamber (3) .

  As described above, by forming the lubricating structure of the syringe (10), the liquid (5) accumulated in the liquid storage chamber (3) can be moved to the sliding portion (1 between the outer cylinder portion (20) and the gasket (30) And the liquid (5) can be used as a lubricant to reduce the sliding resistance between the outer tubular portion (20) and the gasket (30). This reduction in sliding resistance can make it easier to pull the plunger (40) to the front.

(Sliding performance test of syringe)
Next, the sliding performance test of the syringe (10) and the results thereof will be described. In this sliding performance test, the sliding resistance value between the outer cylindrical portion (20) and the gasket (30) when the plunger (40) of the syringe (10) is pulled forward is a product of the present invention and a conventional product. And compared.

  First, the gasket (30) is inserted into the outer cylinder (20) of the syringe (10) of the present invention to a predetermined position. Thereafter, the tip of the nozzle (21) is attached to the chemical solution (5) as liquid, and the plunger (40) is pulled forward to fill the storage chamber (4) of the outer cylinder portion (20) with the chemical solution (5).

  After filling the drug solution (5), the plunger (40) is pushed to form a recess (34) by the rib (23) in the gasket (30), and the storage chamber (4) is formed through the fluid passage (2) by the recess (34). Supply a predetermined amount of the chemical solution (5) of 4) to the liquid storage chamber (3) of the gasket (30). In the case of the conventional product, since there is no rib (23), after filling the storage chamber (4) with the chemical solution (5), the axial position of the gasket (30) is adjusted to be the same position as the product of the present invention.

  Next, the stress when pulling the plunger (40) at a speed of 500 mm / min is measured. This stress is the sliding resistance value between the outer cylindrical portion (20) and the gasket (30). This test was performed five times for each of the product of the present invention and the conventional product. The results are shown in FIG.

  As can be seen from FIG. 6, in the product of the present invention, the sliding resistance value is reduced to about 1/5 that of the conventional product. From this, the product of the present invention has the remarkable effect of being easy to pull the plunger (40) as compared with the conventional product.

  As the amount of drug solution in the liquid storage chamber (3) increases, the sliding resistance of the syringe (10) decreases. From this, as the amount of chemical solution in the liquid storage chamber (3) increases, the amount of chemical solution (5) entering the sliding portion (1) between the outer cylinder portion (20) and the gasket (30) increases. It is believed that the lubrication of the moving part is promoted to improve the sliding performance.

(Endoscope inspection using a syringe)
Next, an endoscopic examination using this syringe will be described.

  This syringe is used, for example, for injecting a drug solution through an endoscope.

  After the endoscope is inserted into the body, the tip of the syringe (10) is attached to the opening formed in the endoscope. The drug solution is filled in the storage chamber (4) of the syringe (10), and the plunger (40) of the syringe (10) is pushed to cause the drug solution in the storage chamber (4) to flow out of the syringe (10). The medicinal solution passes through the internal passage of the endoscope and is sprayed into the body from the forceps port of the endoscope.

  At this time, even if the plunger (40) of the syringe (10) is pushed down, the drug solution remains in the endoscope. In order to discharge the remaining drug solution from the endoscope, the syringe (10) is once removed from the endoscope, and then the plunger (40) is pulled to introduce air into the storage chamber (4) of the syringe (10). Let it flow. After that, the syringe (10) into which air has flowed is attached to the endoscope again, and the plunger (40) is pushed to expel the air in the storage chamber (4) from the syringe (10). It is designed to discharge the drug solution remaining inside.

  With the syringe (10) of the above-described embodiment, the plunger (40) can be pulled more smoothly than with a conventional syringe. As a result, air can be easily flowed into the storage chamber (4) of the syringe (10), and after the air-filled syringe (10) is mounted on the endoscope again, the plunger (10) of the syringe (10) 40) can be pushed to send the air in the syringe (10) to the endoscope, and the drug solution remaining in the endoscope can be easily discharged.

(Other embodiments)
In one embodiment, although a plurality of ribs (23) are formed in the outer cylindrical portion (20) to form the liquid passage (2), the present invention is not limited thereto. For example, the outer peripheral portion of the outer cylindrical portion (20) It is possible to partially project radially outward to form a gap between the inner peripheral wall (22) of the projecting portion and the gasket (30), and to form a liquid passage (2) in the gap. Thus, the fluid passage (2) can be formed without partially deforming the gasket (30). Even in such a case, the same effect as that of the present invention can be obtained.

  In one embodiment, the length L1 of the rib (23) of the syringe (10) is L2 <L1 <L3. However, the present invention is not limited thereto, and L3 ≦ L1 may be satisfied. The length L1 of the rib (23) may be extended rearward than the rear end face of the rear large diameter portion (33). In this case, the liquid (5) in the liquid passage (2) can be supplied to the liquid reservoir adjacent to the rear side of the sliding portion of the rear large diameter portion (33). The sliding part of 33) can also be lubricated.

  As described above, the present invention relates to a syringe, and is particularly useful for measures to reduce the sliding resistance of a gasket inserted in the outer cylinder of the syringe.

1 sliding portion 2 liquid passage 3 liquid reservoir (liquid reservoir)
DESCRIPTION OF SYMBOLS 4 accommodation room 5 liquid 10 syringe 11 sliding part 20 outer cylinder part 21 nozzle 22 inner peripheral wall 23 rib 24 end wall 30 gasket 31 small diameter part 32 front large diameter part (large diameter part)
33 Rear side large diameter part 40 plunger

Claims (6)

An end wall through which the nozzle passes,
An outer tube portion whose end wall is connected to one end;
A gasket made of an elastic body and sliding in the outer cylinder portion back and forth;
The gasket comprises a plunger connected to the tip,
The outer cylindrical portion has a liquid reservoir adjacent to the rear side of the sliding portion of the gasket,
The gasket has at least one each of a small diameter portion separated from the outer cylindrical portion and a front large diameter portion continuously formed on the front side of the small diameter portion, and a back of the rearmost small diameter portion of the gasket A sliding portion is formed between the outer cylindrical portion and the front large diameter portion and the rear large diameter portion, and the outer cylindrical portion has a rear large diameter portion continuously formed on the side; The liquid reservoir is formed in a radial gap between
With the gasket advanced to close the through-hole of the nozzle of the end wall, a gap is formed between the gasket and a portion of the end wall outside the outer peripheral edge of the through-hole, and the gasket A liquid passage which opens in a gap and communicates with the liquid storage portion, and which is formed adjacent to the side of the gasket so as not to communicate the gap with the sliding portion of the rear large diameter portion After the through hole of the nozzle is closed by the gasket, the gasket is pushed forward by the plunger and pressed against the end wall for elastic deformation so as to contract the gap, and along with the contraction of the gap A syringe characterized in that a liquid in a gap is sent to the fluid reservoir through the fluid passage. The outer cylinder portion includes a rib protruding radially inward from an inner peripheral wall,
The syringe according to claim 1, wherein the liquid passage is formed in a recess formed by deformation of a portion of the rib that rides on the rib when sliding in the front-rear direction of the gasket. The syringe according to claim 2, wherein the rib of the outer cylindrical portion is formed such that an axial length thereof is longer than an axial length of the front large diameter portion of the gasket.   The syringe according to claim 2 or 3, wherein a plurality of ribs of the outer cylinder part are formed at intervals in the circumferential direction of the one or the outer cylinder part. In the outer cylindrical portion, a groove extending in the axial direction is formed in the inner peripheral wall,
The syringe according to claim 1, wherein the liquid passage is formed inside the groove. The tip of the gasket is formed in a conical shape,
The end wall is formed in a tapered shape expanding in diameter from the outer peripheral edge of the through hole to the outer peripheral edge of the end wall,
Wherein the apex angle of said conical tip portion is smaller than the taper angle of the end wall, the syringe according to any one of claims 1 to 5.